CN1210873C - Transmitting system for carrying different encoding principles - Google Patents
Transmitting system for carrying different encoding principles Download PDFInfo
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- CN1210873C CN1210873C CNB011197366A CN01119736A CN1210873C CN 1210873 C CN1210873 C CN 1210873C CN B011197366 A CNB011197366 A CN B011197366A CN 01119736 A CN01119736 A CN 01119736A CN 1210873 C CN1210873 C CN 1210873C
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/66—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission for reducing bandwidth of signals; for improving efficiency of transmission
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/66—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission for reducing bandwidth of signals; for improving efficiency of transmission
- H04B1/667—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission for reducing bandwidth of signals; for improving efficiency of transmission using a division in frequency subbands
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Abstract
In a transmission system for transmitting speech and music signals, an input signal is split up into two spectral portions in a coder. These spectral portions are coded each by its own sub-coder. The transmission quality may be improved considerably by coding according to the inventive idea a spectral portion by a time-domain coder.
Description
Technical field
The present invention relates to a kind of transmitting system, the transmitter of this transmitting system has an encoder, be used for input signal is encoded, this encoder comprises the time domain coding device, derive digitally encoded signal from the portions of the spectrum of input signal, transmitter also has emitter, will send to receiver through digitally coded signal by send channel, the decoder of receiver comprises the time domain decoder, is used for from obtain the signal through decoding through digitally coded signal.
The invention still further relates to transmitter, receiver, the encoder used in this transmitting system, and a kind of method that sends Code And Decode.
Background technology
From the U.S. Patent application GB2188820 that has announced, can recognize described the sort of transmitting system of this specification beginning.
This class transmitting system sends speech signal or music signal in order to for example channel by finite capacity usually.
First example of this channel is the radio channel between mobile radio station and the fixed base platform.The number of users of this channel is big, so its spendable transmission capacity is subjected to certain limitation.Second example is the record channel that uses on magnetic, light or other recording medium, for example ROM (read-only memory).Here capacity also often is restricted.
In the transmitter of the transmitting system of described UK Patent Application, the portions of the spectrum of input signal is transformed into digitally encoded signal by the time domain coding device.
The example of time domain coding device has the encoder that adopts following modulation system: pulse-code modulation, adaptive differential pulse-code modulation, delta modulation, auto-adaptive increment modulation, the various coding methods of vector quantization (CELP) and employing linear prediction.When using transmitting device, send to receiver by channel through digitally coded signal.The time domain decoder from encoded signal obtain through the decoding signal.
A problem of prior art transmission system is that no matter as which kind of purposes, its quality of the signal that reconstitutes is defective because of desired transfer rate.
Summary of the invention
The purpose of this invention is to provide described the sort of transmitting system of this specification beginning, reconstitute quality of signals in the system and be improved, perhaps can reduce desired transfer rate reconstituting under the constant situation of quality of signals at the transfer rate invariant.
For reaching this purpose, the present invention has following characteristics: encoder comprises that also a transform domain coding device obtains another through digitally coded signal for another portions of the spectrum from input signal, transmitter also disposes to such an extent that make it send receiver with this another to through digitally coded signal by transmitting channel, this connects receiver a transform domain decoder and synthesizer, the former in order to from this another through digitally coded signal obtain another through the decoding signal, the latter in order to from through the decoding signal and this another through the decoding signal obtain the signal that reconstitutes.
The present invention is based on such understanding, be that the time domain encoder is in optimum state under a certain portions of the spectrum of output signal, the transform domain coding device is in optimum state under another portions of the spectrum, the example of transform domain coding device has the encoder of using subband coding, and uses the encoder that spatial transform is become the various coded systems in another kind of territory.This class is transformed to for example discrete Fourier transform, discrete cosine transform or discrete Walsh-Hadamard transform.At this moment can also can unfavorable personnel selection auditory system and tonequality performance.Under dividing, the variant frequency spectrum of input signal uses the time domain coding apparatus respectively or the transform domain coding device can significantly improve the quality of signals that reconstitutes.
Should be noted that German patent specification .DE2605306 C2 discloses a kind of transmitting system, the input signal in the system is divided into the portions of the spectrum of representing baseband signal and another portions of the spectrum of representing a plurality of frequency-division section signals.But the relevant signal in this transmitting system transmits with analog form, thereby need not encoder.Obviously in this Deutsche Bundespatent transmitting system analog signal is carried out digitally coded problem without any effect.
Most preferred embodiment of the present invention is characterised in that the frequency that is positioned at portions of the spectrum is lower than the frequency that is positioned at another portions of the spectrum.
Experiment showed, at 0 hertz and to several conspicuous low frequencies, use the time domain coding device, in higher frequency range, use transform domain coding, can both significantly improve the quality of signals that reconstitutes.
Description of drawings
Referring now to accompanying drawing, further specify content of the present invention, similar elements is with similarly numbering and letter representation in the accompanying drawing.
Fig. 1 shows a transmitting system of the present invention.
Fig. 2 shows the subband coding device that uses in the transmitting system shown in Figure 1.
Fig. 3 shows the frequency-division section decoder that uses in the transmitting system shown in Figure 1.
Fig. 4 shows the choice device that uses in the segment encoding device shown in Figure 2.
Fig. 5 shows the program flow diagram of the processor 118 that uses in the choice device shown in Figure 4.
Fig. 6 is the schematic diagram of the benchmark envelope that uses in Fig. 2 and the encoder shown in Figure 3, and each envelope is with four value representations.
Fig. 7 is the schematic diagram of the benchmark envelope that uses in Fig. 2 and the encoder shown in Figure 3, and each envelope is with eight value representations.
Fig. 8 represents transmitting system according to an embodiment of the invention.
Embodiment
In transmitting system shown in Figure 1, input signal is added on the transmitter 2.The input of filter 50 in the input encoder 51 of transmitter 2.The input of the first output termination delay element 62 of filter 50.The output signal of filter 50 first outputs is represented the portions of the spectrum of input signal.The input of the output termination time domain coding device of delay element 62, in the case, the time domain coding device is an employing linear prediction (LPC: vector quantizer 66 linear predictive coding).The output of vector quantizer 66 is exported through digitally coded signal, and links to each other with the first input end of R-T unit, and this emitter is multiplexer 68 in the case.
Each connects the input of transform domain coding device a plurality of outputs of filter 50, and the transform domain coding device is a subband coding device 64 in the case.This another portions of the spectrum of the expression input signal that the input signal of subband coding device 64 is total.The output of subband coding device 64, transmitting its output signal this another through digitally coded signal, connect second input of multiplexer 68.
The output channel 4 of multiplexer 68 is connected to the input of receiver 6.In receiver 6, signal is added to the input of splitter 70.First output of splitter 70 is transmitting its output signal through digitally coded signal, and joins with the time domain decoder, and in the case, the time domain decoder is for adopting the inverse vector quantizer 84 of linear prediction.The output of inverse vector quantizer 84 is transmitting the signal that reconstitutes of its output signal, connects the input of retardation element 86.The output of retardation element 86 is bonded into the first input end of device 88.The input of the second output termination transform domain decoder of demultiplexer 70, the transform domain decoder is a frequency-division section decoder 72 in the case.A plurality of outputs of frequency-division section decoder 72 are transmitting the signal that reconstitutes of the output signal of its total this another portions of the spectrum of expression input signal, and each is bonded into the input of device 88.The input signal that reconstitutes appears at the output of synthesizer 88.
Filter 50 is divided into a portions of the spectrum and another portions of the spectrum with the input signal of transmission system shown in Figure 1.Portions of the spectrum is transformed into through digitally coded signal by vector quantizer 66.Vector quantizer 66 suitable applicable cases have introduction in for example CCITT (CCITT) G728 recommendation " coding that speech carries out with the linear prediction of low delay sign indicating number excitation " under 16 kbps.This encoder is by the work of " synthesis analysis " rule.
In this vector quantizer, input signal to be encoded is transformed into the continuous signal section of being made up of a plurality of signal samplings of signal to be encoded.Produce the composite signal section that is stored in a large amount of code book words in the code book with a composite filter.Between the actual signal section of input signal and the composite signal section difference by perceptual weighting filter (Perceptual Weighting filter) filtering.The quadratic sum of signal sampling is calculated from the sample section of perceptual weighting filter output signal.
The generation of composite signal, the calculating of the difference between input signal and the composite signal, the filtering of carrying out with perceptual weighting filter and the calculating of quadratic sum, these all are the processing that all will carry out each 1024 existing code book word.From these code book word selects get can produce least square and the code book word.
The analysis filter tansfer function is to determine by the relation between each continuous sampling in four signal segments of composite signal before the linear prediction estimation actual signal section.At this moment encoded signal contains the code book index of selected code book word.Should be noted that each Prediction Parameters need not conversion.
The frequency-division section signal indication of described another portions of the spectrum of input signal on filter 50 outputs.These frequency-division section signals by subband coding device 64 be transformed into described another through digitally coded signal.Should be noted that the passband signal in the suitable frequency-division section of filter 50 output frequency-division section signal indications.The benefit of this baseband representation method is that the sampling that each frequency-division section needs is not definite but definite by the bandwidth of suitable frequency-division section by the highest frequency of suitable frequency-division section.From draft internation standard ISO/IEC DIS 11172 " information technology is up to the coding of the 1.5 megabit per second left and right sides digital storage medias audio frequency relevant with animation " the 3rd joint, know in the 174th~337 page, to sampling rate is 48 kilo hertzs signal, is advisable to adopt subband coding device 64.The frequency-division section signal of input is by quantizing to be transformed into digital signal.The frequency-division section signal quantizes under a series of level, the frequency-division section difference, and level may be different.The actual number of the quantization level that each frequency-division section uses depends on the power of the frequency-division section signal of the power of relevant frequency-division section signal and near frequency-division section.Utilize people's auditory system can hear near this performance of the weak signal that strong signal is then.So just can quantize the weak signal of this quantization level more than strong signal much less.Can calculate each frequency-division section according to the power of various frequency-division section signals just can audible noise level.Data based this noise level of the quantization level of each frequency-division section signal demand is determined.At this moment another through digitally coded signal comprise various through quantizing the frequency-division section signal and about the information of each frequency-division section quantization level number.Should be noted that described encoder is to establish for the signal of 0-24 kilohertz is encoded.Since by time domain coding device coding, the frequency-division section that is positioned at this spectrum region just need not to encode portions of the spectrum.This however assigning any binary digit for these frequency-division sections gets final product.
Multiplexer 68 will through digitally coded signal and another be through the synthetic signal of digitally coded signal.Delay cell 62 arrives each portions of the spectrum of the input signal of multiplexer 68 along two paths in order to equilibrium.Transmitter sends to receiver with this composite signal by channel.Composite signal is divided into through digitally coded signal in receiver again and another is through digitally coded signal.Be transformed into the signal that reconstitutes by inverse vector quantizer 84 through digitally coded signal.Introduced in the G728 recommendation of above-mentioned CCITT and how suitably used the frequency-division section decoder.In this inverse vector quantizer 84, vector quantizer 66 selected code book radicals produce according to the code book index that is transmitted.The code book word by composite filter be transformed into through the decoding signal.For this purpose, the parameter of composite filter is obtained from four signal segments before the actual signal section of decoding by linear prediction.This is undertaken by encoder 66 similar modes.
Another is transformed into a plurality of frequency-division section signals through decoding on the output that appears at frequency division decoder 72 itself by frequency-division section decoder 72 through digitally coded signal.Should be noted that these frequency-division section signals are basic signals of the bandpass signal in the relevant frequency-division section of expression.The benefit of this baseband representation method is that the required sampling of unit frequency-division section is not to depend on the highest frequency of branch frequency band but the bandwidth that depends on relevant frequency-division section.Synthesizer 88 becomes desired frequency-division section frequency with the frequency-division section conversion of signals, then with these signals and the synthetic input signal that reconstitutes of the signal through decoding.
In the subband coding device 64 shown in Fig. 2, each frequency-division section signal all is added to segment encoding device 91 separately ... 100.Subband coding device 91 ... 100 structure is all identical.The input termination sectioning 90 of subband coding device 91.The input of the output termination determinator 92 of sectioning 90 and the input of scaler 94.The first input end of the second output termination multiplexer 102 of the power measurement value of its output signal is being transmitted in the control input end of the first output termination scaler 94 of determinator 92, determinator.The input that the input of the output termination absolute calculators 95 of scaler 94 and symbol are determined device 98.The input of device 96 is selected in the output selecting of absolute calculators.The output of choice device 96 is transmitting the identification code of its selected benchmark envelope, connects the input of multiplexer 102.Symbol is determined the 3rd input of the output termination multiplexer 102 of device.The output of multiplexer 102 forms the output of subband coding device 64.
Transmitting highest frequency is that the frequency range of portions of the spectrum is the 0-2 kilohertz among 8 kilo hertzs the embodiment of encoder 51 of transmitting system of sound signal, and the frequency range of another portions of the spectrum is 2 kilo hertzs to 8 kilo hertzs.This another portions of the spectrum eight frequency-division section signal indications of subband coding device 64 input ends.The frequency-division section signal is at subband coding device 91 ... be segmented into identical a plurality of signal segments of duration in 100, the sampling number of frequency-division section signal is directly proportional with the bandwidth of frequency-division section signal in the signal segment.Table 1 has been listed the frequency range and the corresponding sampling number of each signal segment of each frequency-division section.The duration of signal segment is 4 milliseconds.
Table 1
Frequency-division section i | F minimum [kilohertz] | F the highest [kilohertz] | Δ f[kilohertz] | 1 signal segment of |
1 | 2 | 2.5 | 0.5 | 4 |
2 | 2.5 | 3 | 0.5 | 4 |
3 | 3 | 3.5 | 0.5 | 4 |
4 | 3.5 | 4 | 0.5 | 4 |
5 | 4 | 5 | 1 | 8 |
6 | 5 | 6 | 1 | 8 |
7 | 6 | 7 | 1 | 8 |
8 | 7 | 8 | 1 | 8 |
Sending highest frequency is that the frequency range of portions of the spectrum is the 0-4 kilohertz among 16 kilo hertzs the embodiment of encoder 51 of transmission system of sound signal, and the frequency range of another portions of the spectrum is 4 kilo hertzs to 16 kilo hertzs.Another frequency partly has 8 frequency-division section signal indications of subband coding device 64 outputs.These frequency-division section signals are at subband coding device 91 ... also be segmented into many signal segments of duration in 100, the number of frequency-division section sampling is directly proportional with the bandwidth of this frequency-division section signal in the signal segment.Table 2 has been listed the frequency range and the corresponding sampling number of each signal segment of each frequency-division section.The duration of signal segment is 2 milliseconds.
Frequency-division section i | F minimum [kilohertz] | F the highest [kilohertz] | Δ f[kilohertz] | 1 signal segment of |
1 | 4 | 5 | 1 | 4 |
2 | 5 | 6 | 1 | 4 |
3 | 6 | 7 | 1 | 4 |
4 | 7 | 8 | 1 | 4 |
5 | 8 | 10 | 2 | 8 |
6 | 10 | 12 | 2 | 8 |
7 | 12 | 14 | 2 | 8 |
8 | 14 | 16 | 2 | 8 |
Determinator 92 is measured the power measurement value of the relevant signal segment of each frequency-division section signal sampling.This power measurement value converts logarithm power measurement value to, and the difference between the logarithm power measurement value of the signal segment before the logarithm power measurement value of actual signal section and the actual signal section is then with Huffman encoding method coding.Signal through Huffman encoding is added on the multiplexer 68, and this signal sends receiver 6 to.The another kind of method of the power measurement value coding of different frequency-division sections is to encode to the power measurement value of concrete frequency-division section with about the difference between the power of the power of frequency-division section and all the other frequency-division sections.The power measurement value of variant frequency-division section is relative to each other and can saves transmission capacity greatly.Scaler 94 bases are demarcated frequency-division section signal sampling value from the control signal of determinator, thereby make the performance number of each signal segment on scaler 94 outputs constant.Absolute value generator 95 produces the envelope of scaler 94 output signals, and the form of this envelope with segmentation is added on the choice device 96.Choice device is compared the envelope of scaler 94 output signals with a series of benchmark envelopes, and chooses the benchmark envelope the most suitable with the envelope of scaler 94 output signals.Choice device produces the identification code of selected benchmark envelope on its output.Identification code is added on the multiplexer 102 so that send to receiver 6.In every signal segment adopts the frequency-division section of frequency-division section signal sampling of 4 frequency-division section signal samplings, adopt 5 benchmark envelopes, in every signal segment adopts the frequency-division section signal of 8 frequency-division section signal samplings, adopt 11 benchmark envelopes.
The benchmark envelope number that adopts in the frequency-division section of 8 the frequency-division section signal samplings scope at 1-11 is arranged.Because the power measurement value is carried out Huffman encoding, this power measurement is worth needed number of bits may be different with the difference of signal segment.If therefore make the long identification code of transmission benchmark envelope, thereby can come with relatively large benchmark envelope the envelope of scaler 94 output signals is encoded.
Symbol is determined the symbol of device 98 definite scaler 94 output signals.This symbol is added on the 3rd input of multiplexer 102 so that send to receiver 6.The symbol of scaler 94 output signals can all send to receiver, and produces this symbol by the noise generator of receiver end.Higher frequency-division section be it seems especially feasible during this simplification.
In the frequency-division section decoder 72 shown in Fig. 3, the output signal of demultiplexer 70 is added on the demultiplexer 104.Each frequency-division section decoder 106 ... 114 all are added with three output signals of demultiplexer 104.First of these outputs received benchmark envelope generator 108.Second first input end of receiving multiplier circuit 110 of these outputs, the 3rd first input end of receiving multiplier circuit 112 of these outputs.But the 3rd output that yet it is contemplated that demultiplexer 104 does not exist, and the first input end of multiplier circuit 112 connects the output of noise generator 109.Second input of the output termination multiplier circuit 110 of benchmark envelope generator 108.Second input of the output termination multiplier circuit 112 of multiplier circuit 110.The output of multiplier circuit 112 forms one of them signal through the frequency-division section signal of decoding.Frequency division decoder 106 ... 114 similar.
Benchmark envelope generator 108 produces selected benchmark envelope according to the identification code of being received.Multiplier circuit 110 is on duty with selected benchmark envelope and power measurement, thereby draws the envelope that relevant frequency-division section signal has reconstituted.The envelope that the frequency-division section signal has reconstituted multiplies each other with symbol that the frequency-division section signal sampling is received in multiplier circuit 112, thereby draws frequency-division section signal through decoding at the output of multiplier circuit 112.When shifting, multiplier circuit 112 multiplies each other the output signal of multiplier circuit 110 and the output signal of noise source 109 as for the sampling symbol of frequency-division section frequency-division section signal.
In choice device shown in Figure 4, transmit four 4 inputs importing termination processors 118 of four absolute values of the frequency-division section signal that synthesizes a signal segment through converting for its input signal.Among Fig. 2,4 inputs of this of choice device 96 schematically illustrate with single input.First output of processor 118 is transmitting the address signal of its output signal, connects the input of ROM116.Four outputs of ROM116 are transmitting the benchmark envelope of representing its output signal, connect other 4 inputs of processor 118.Second output of processor 118 is transmitting the identification code of its output signal benchmark envelope, forms the output of choice device 96.
Suppose in choice device shown in Figure 4 96, the envelope of scaler 94 output signals with this envelope with four value representations of this envelope in continuous time.Suppose that also the benchmark envelope all uses four value representations of these benchmark envelopes.In choice device 96, processor produces the continuation address of ROM116.This ROM16 provides the benchmark that is stored in this address envelope with the form of four values.Processor 118 reads the value of expression benchmark envelope and scaler 94 output signal envelope lines.Processor 118 produces the difference measured value between two envelopes, this measured value for example equal between each represented analog value of envelope the difference of two squares and.Processor produces the address of all preparations in order to benchmark envelope relatively successively, and produces the identification code of benchmark envelope together with minimizing poor measured value at second output.Can see that when the envelope in the frequency-division section was represented with 8 signal samplings, choice device should have 8 inputs.Therefore ROM116 has 8 outputs, thereby each input port of processor 118 also should have 8 inputs.
For carrying out above-mentioned functions, processor 118 should have suitable program, and the flow chart of this program as shown in Figure 5.Each instruction its connotation of having compiled number is as shown in the table.
Numbering instruction connotation
120 START begin executive program
122 MIN:=Z make the value of variable MIN equal constant Z.
124 READ SEGMENT read the value of the envelope of expression signal segment.
126 SHAPENO:=1 choose the first benchmark envelope.
128 READ SHAPE read each value of expression benchmark envelope.
130 CACULATE SQDIFF calculate benchmark envelope and signal segment envelope
Between the difference of two squares.
132 SQDIFF<MIN? whether test SQDIFF (difference of two squares) is less than MIN.
134 MIN:=SQDIFF make the value of variable MIN equal variable SQDIFF.
136 INDEX:SHAPENO store the sign of optimal criteria envelope so far.
138 SHAPENO=N? test all benchmark envelopes and be all and signal
The section envelope is mistake relatively.
140 SHAPENO:=choose next benchmark envelope.
142 WRITE INDEX are placed on processing with the identification of selected benchmark envelope
On second output of device.
The program of Fig. 5 flow chart all will be carried out once each signal segment of frequency-division section sample of signal.In the square frame 122, the variable MIN of order expression minimal error measured value equals digital Z, and Z is big, and the lowest difference measured value that must make does not reach this digital Z.Then in square frame 124.Read each value of expression signal segment envelope by processor 118.In square frame 126, the address that order belongs to the first benchmark envelope appears on first output of processor.In square frame 128, read the difference measured value of representing between envelope and the benchmark envelope by processor.Difference measured value SQDIFF can calculate with following formula:
(1) in the formula, i is an operating parameter, and L is the number of the value of expression envelope, and xi is an i value of the value of expression signal segment envelope, and yi then is an i value of the value of expression benchmark envelope.
In square frame 132, the value of 5QDIFF is compared with the value of MIN.If the value of SQDIFF is less than the value of MIN, then the corresponding relation of reference envelope and signal segment envelope is than darker with the corresponding relation of the benchmark envelope of once relatively crossing with the envelope of signal segment.In the case, make MIN that the value in square frame 134 equals the value of SQDIFF.In addition, in square frame 136, the darkest INDEX value of identification code corresponding relation so far of order expression benchmark envelope equals present benchmark envelope identification code.If the value of SQDIFF is not less than the value of MIN, then skip block 134 and 136.
At square frame 138, check all benchmark envelopes whether all with the envelope of frequency-division section signal sampling signal segment mistake relatively.If mistake relatively entirely, then in square frame 142, write the variable INDEX of the identification code of the darkest benchmark envelope of expression and the envelope corresponding relation of frequency-division section signal sampling signal segment.If gold relatively, then all benchmark envelopes that will participate in comparison must be compared with the envelope of frequency-division section signal sampling signal segment, select next benchmark envelope at square frame 140, change square frame 128 then over to.
Should be noted that encoder can be fully realizes with the form of hardware, but also encoder and/or decoder can be combined in the signal processor wholly or in part.At this moment signal processor is controlled by appropriate software.
Fig. 6 shows five benchmark envelopes as frequency-division section, four value representations of this frequency-division section.Benchmark envelope Yk, the i value representation, wherein K is the sequence number of benchmark envelope, i is a sequence number of determining the value of benchmark envelope.The frequency that experiment showed, not all benchmark envelope appearance is all the same.This phenomenon can for example reduce to transmit the needed transmission capacity of identification code of benchmark envelope by Huffman encoding.
Illustrated among Fig. 7 with employed 11 the benchmark envelopes of the frequency-division section of 18 value representations.Here experiment is proof also, and the frequency that not all benchmark envelope occurs all equates.
Be noted that except that fixing benchmark envelope, can also adopt the self adaptation benchmark envelope that draws from frequency-division section signal to be encoded, or replace fixing benchmark envelope with this envelope.
In transmission system shown in Figure 8, input signal is added on the transmitter 2.The input of filter 50 in the input termination encoder 51 of transmitter 2.The input of the first output termination delay cell 62 of filter 50 and the input of subtraction circuit 65.Input signal on filter 50 first ends is represented the portions of the spectrum of input signal.The input of the output termination time domain coding device of delay element, the time domain coding device is for using linear prediction (LPC: vector quantizer 66 linear predictive coding) in the case.The output of vector quantizer 66, transmitting its output signal first through digitally coded signal, the first input end and the time domain decoder 67 of its sending and receiving injection device (being multiplexer 68 in the case).Second input of the output termination subtraction circuit 65 of time domain decoder 67.
The a plurality of outputs of filter 50 and the output of subtraction circuit 65 connect the input of transform domain coding device respectively, and in the case, the transform domain coding device is made of subband coding device 64.Each input signal of subband coding device 64 is represented the combination of portions of the spectrum He another portions of the spectrum of input signal together.The output of subband coding device 64, another that is transmitting its output signal is through digitally coded signal, and it links to each other with second input of multiplexer 68.
The output channel 4 of multiplexer 68 is connected to the input of receiver 6.Signal is added on the input of demultiplexer 70 in receiver 6.First output of demultiplexer 70 is transmitting its output signal through digitally coded signal, and it links to each other with the time domain coding device, and in the case, the time domain coding device is for adopting the inverse vector quantizer 84 of linear prediction.The output of inverse vector quantizer 84 is transmitting the signal of its output signal through decoding, connects the input of delay cell 86.The first input end of the output termination adder circuit 87 of delay cell 86.The output of adder circuit 87 is bonded into the first input end of device 88.The input of the second input termination transform domain decoder of demultiplexer 70, in the case, the transform domain decoder is a frequency-division section decoder 72.A plurality of outputs of frequency-division section decoder 72 are transmitting the signal that the output signal of another portions of the spectrum of total expression output signal reconstitutes, and each is bonded into the input of device 88.Second input of adder circuit 87 is received in the output of frequency-division section decoder 72 expression input signal spectrum parts.The signal that reconstitutes appears at the output of synthesizer 88.
The input signal of transmitting system shown in Figure 8 is divided into portions of the spectrum and another portions of the spectrum by filter.Portions of the spectrum is transformed into through digitally coded signal by vector quantizer 66.With reference to Fig. 1 the practical situation that vector quantizer 66 is suitable was described above.Be transformed into signal through decoding through digitally coded signal by time domain decoder 67, this signal through decoding is the subtrahend that is deducted from the portions of the spectrum of input signal by subtraction circuit 65.At this moment the encoding error signal of the encoding error of expression time domain coding device has just appearred in the output of subtraction circuit.
Another portions of the spectrum of input signal is by the frequency-division section signal indication on filter 50 outputs.Encoding error signal on these frequency-division section signals and subtraction circuit 65 outputs is transformed into another signal through numeral by subband coding device 64.Expand through time domain decoder 67 and subtracter 65, any encoding error of time domain coding device 66 just can be encoded once more by subband coding device 64, and sends encoding error to receiver.These measures can improve transmission quality.It is very not complicated to reach this purpose, because in the analysis-by-synthesis time domain coding device time domain decoder has been arranged.The signal of the input signal of subtraction circuit 65 and an expression number portions of the spectrum is necessary to postpone the regular hour makes all input signals of subband coding device 64 all postpone the same time.
Should point out that the frequency-division section signal on filter 50 outputs is the baseband signal of the bandpass signal in this special frequency-division section of expression.The benefit of this baseband representation method is that the desired sampling number of per minute frequency range does not depend on the highest frequency of this specific frequency-division section and depends on the bandwidth of this specific frequency-division section.From draft internation standard ISO/IEC DIS 11172 " information technology one is up to the coding of the 1.5 megabit per second left and right sides digital storage medias audio frequency relevant with animation " the 3rd joint, know in the 174-337 page or leaf, to sampling rate is 48 kilo hertzs signal, is advisable to adopt subband coding device 64.The frequency-division section signal of input is by quantizing to be transformed into digital signal.The frequency-division section signal is by quantizing to be transformed into digital signal.The frequency-division section signal quantizes under a series of level, the frequency-division section difference, and level may be different.The actual number of the quantization level that each frequency-division section uses depends on the power of the frequency-division section signal of the power of this specific frequency-division section signal and near frequency-division section.Utilize people's auditory system can hear near this performance of the weak signal the strong signal then, so just can quantize this quantization level more than the weak signal of signal much less by force.Can calculate each frequency-division section according to the power of various frequency-division section signals just can audible noise level.This noise level of quantization level data of each frequency-division section signal demand is determined.At this moment another through digitally coded signal comprise various through quantizing the frequency-division section signal and about the information of each frequency-division section quantization level number.Should be noted that described encoder is to establish for the signal of 0-24 kilohertz is encoded.Because by time domain coding device coding, the frequency-division section that is positioned at this spectrum region only contains the less encoding error signal of amplitude to the portions of the spectrum of 0-24 kilohertz.Like this, branch is tasked these frequency-division sections and can therefore almost not need not to increase any transmission capacity and come transmission capacity to transmit this encoding error signal more than several binary digits.
Multiplexer 68 will synthesize a signal through digitally coded signal through digitally coded signal and another.Delay cell 62 is to establish along the time-delay that two paths arrive the input signal spectrum part of multiplexer 68 for equilibrium.Transmitter sends to receiver with this composite signal by channel.Composite signal is divided into through digitally coded signal in receiver once more and another is through digitally coded signal.Be transformed into first signal that reconstitutes through digitally coded signal by the inverse vector quantizer.Introduced in the G728 recommendation of above-mentioned CCITT and how suitably used the frequency-division section decoder.
Another is transformed into a plurality of frequency-division section signals through decoding that occur at the output of frequency-division section decoder 72 through digitally coded signal by frequency-division section decoder 72.The minimum frequency-division section output signal (0-4 kilohertz) of presentation code error signal is added on delay cell 86 outputs signal through decoding by adder circuit 87 and draws signal through decoding.
Be noted that these frequency-division section signals on the output of frequency-division section decoder 72 are baseband signals of bandpass signal in this specific frequency-division section of expression.The benefit of this baseband representation method is, the required sampling number of per minute frequency range does not depend on the highest frequency on this specific frequency-division section and depends on the bandwidth of this specific frequency-division section.Synthesizer 88 becomes desired frequency-division section frequency with frequency-division section signal transformation, then frequency-division section signal and the signal through decoding is synthesized the input signal that reconstitutes.
Claims (9)
1. a transmission system comprises a transmitter and a receiver, it is characterized in that:
This transmitter comprises a code device, and this code device comprises:
A time domain coding device is used for carrying out time domain coding by first portions of the spectrum to input signal and obtains an independent time domain coding digital audio and video signals, and described first portions of the spectrum has at least to 2kHz but do not exceed the frequency band of 4kHz;
A transform domain coding device, be used for carrying out transform domain coding to obtain the digital signal of a transform domain coding by second portions of the spectrum to this input signal, described second portions of the spectrum has the frequency band that is higher than described first portions of the spectrum and has obviously bigger bandwidth;
Described transform domain coding device comprises a plurality of sub-encoders, and described a plurality of sub-encoders are used for encoding for the respective sub-bands of a plurality of subbands of described second portions of the spectrum respectively;
This transmitter also comprises a multiplex machine, is used for carrying out multiplexed to obtain a transmission signals to the digital signal of this time domain and domain of variation coding; With a dispensing device, be used for described transmission signals is sent to this receiver via a transmission channel;
This receiver comprises:
The multichannel decomposer is used for the transmission signals that is received is carried out demultiplexing with the digital signal by a digital signal that wherein recovers a time domain coding and a transform domain coding;
A time domain decoder is used for this time domain coding signal is carried out time domain decoding first decoded signal with first portions of the spectrum that obtains described input signal;
A transform domain decoder is used for the digital signal of this transform domain coding is carried out transform domain decoding second decoded signal with second portions of the spectrum that obtains described input signal;
This receiver also comprises the merging device, is used for obtaining a described input signal based on the merging of first and second decoded signals.
2. transmission system as claimed in claim 1 is characterized in that, this time domain coding device comprises a vector quantization coding device, and this time domain decoder comprises a vector quantization decoder device.
3. transmission system as claimed in claim 2 is characterized in that, this time domain coding device also comprises a linear prediction device.
4. transmission system as claimed in claim 1 is characterized in that, this transform domain coding device also comprises a plurality of subband coders, and this transform domain decoder comprises a plurality of sub-band decoder.
5. one kind sends to the method for receiver with input signal by transmitter, may further comprise the steps:
First portions of the spectrum of input signal is carried out time domain coding obtaining an independent time domain coding digital audio and video signals, and described first portions of the spectrum has at least to 2 kHz but does not exceed the frequency band of 4kHz;
Second portions of the spectrum to input signal carries out transform domain coding to obtain the digital signal of a transform domain coding, and described second portions of the spectrum has the frequency band that is higher than described first portions of the spectrum and has obviously bigger bandwidth;
The digital signal of this time domain and domain of variation coding is carried out multiplexed to obtain a synthetic transmission signals, this transmission signals is sent to described receiver;
After described receiver place receives signal, with this transmission signals demultiplexing with digital signal by digital signal that wherein recovers this time domain coding and transform domain coding;
The digital signal of this time domain coding is carried out the time domain decoding with one first digital signal by first portions of the spectrum that wherein recovers described input signal;
The digital signal of this transform domain coding is carried out the transform domain decoding with one second digital signal by second portions of the spectrum that wherein recovers described input signal;
First and second digital signals that recovered are merged to come the described input signal of reconstruct thus
6. one kind is used for the input signal that will send is carried out Methods for Coding, comprising:
First portions of the spectrum of this input signal is carried out time domain coding obtaining an independent time domain coding digital audio and video signals, and described first portions of the spectrum has at least to 2kHz but does not exceed the frequency band of 4kHz;
Second portions of the spectrum to this input signal carries out transform domain coding to obtain the digital signal of a transform domain coding, and described second portions of the spectrum has the frequency band that is higher than described first portions of the spectrum and has obviously bigger bandwidth;
Carry out the digital signal of this time domain and domain of variation coding multiplexed to obtain a synthetic transmission signals.
7. method that the digitally coded transmission signals that is received is decoded comprises:
With the transmission signals that is received separate multiple with by wherein recover one will reconstruct the digital signal of an independent time domain coding of first portions of the spectrum of signal, with one will reconstruct the digital signal of transform domain coding of second portions of the spectrum of signal, wherein said first portions of the spectrum has at least to 2kHz but does not exceed the frequency band of 4kHz, and described second portions of the spectrum has the frequency band that is higher than described first portions of the spectrum and have obviously bigger bandwidth;
This independent time domain coding signal is carried out the time domain decoding, thereby obtain first decoded signal;
The digital signal of this transform domain coding is carried out the transform domain decoding, thereby obtain second decoded signal, described decoding step is earlier by deriving a plurality of transform domain coding digital signals that correspond respectively to each subband of described second portions of the spectrum in this transform domain coding digital signal, and each of described subband is carried out the transform domain decoding; And
First and second decoded signals that recovered are merged form thus will be by the described signal of reconstruct.
8. transmitter, it comprises that is used for the code device that the input signal that will send is encoded, this code device comprises:
A time domain coding device is used for carrying out time domain coding by first portions of the spectrum to input signal and obtains an independent time domain coding digital audio and video signals, and described first portions of the spectrum has at least to 2kHz but do not exceed the frequency band of 4kHz;
A transform domain coding device, be used for carrying out transform domain coding to obtain the digital signal of a transform domain coding by second portions of the spectrum to this input signal, described second portions of the spectrum has the frequency band that is higher than described first portions of the spectrum and has obviously bigger bandwidth;
Described transform domain coding device comprises a plurality of sub-encoders, and described a plurality of sub-encoders are used for encoding for the respective sub-bands of a plurality of subbands of described second portions of the spectrum respectively;
This transmitter also comprises multiplex machine, is used for carrying out the digital signal of this time domain and domain of variation coding multiplexed to obtain a transmission signals.
9. receiver comprises:
The multichannel decomposer is used for the transmission signals that is received is carried out demultiplexing with the digital signal by a digital signal that wherein recovers a time domain coding and a transform domain coding;
A time domain decoder is used for this time domain coding signal is carried out time domain decoding first decoded signal with first portions of the spectrum of the signal that obtains the reconstruct of being wanted, and described first portions of the spectrum has at least to 2kHz but do not exceed the frequency band of 4kHz;
A transform domain decoder, be used for the digital signal of this transform domain coding is carried out second decoded signal of transform domain decoding with second portions of the spectrum of the signal of the acquisition reconstruct of being wanted, described second portions of the spectrum has the frequency band that is higher than described first portions of the spectrum and has obviously bigger bandwidth;
Described transform domain decoder comprises a plurality of sub-decoders, and described a plurality of sub-decoders are used for decoding respectively for a plurality of transform domain coding digital signals corresponding to described second each subband of portions of the spectrum respectively;
Merge device, be used for obtaining the signal of the reconstruct of wanting based on the merging of first and second decoded signals.
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BE9301077 | 1993-10-11 | ||
BE9301077A BE1007617A3 (en) | 1993-10-11 | 1993-10-11 | Transmission system using different codeerprincipes. |
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CN1210873C true CN1210873C (en) | 2005-07-13 |
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CNB011197366A Expired - Lifetime CN1210873C (en) | 1993-10-11 | 2001-05-17 | Transmitting system for carrying different encoding principles |
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1993
- 1993-10-11 BE BE9301077A patent/BE1007617A3/en not_active IP Right Cessation
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1994
- 1994-10-10 MY MYPI94002687A patent/MY112253A/en unknown
- 1994-10-11 RU RU95112470A patent/RU2144261C1/en active
- 1994-10-11 US US08/320,636 patent/US5808569A/en not_active Expired - Lifetime
- 1994-10-11 SG SG1996009053A patent/SG55182A1/en unknown
- 1994-10-11 KR KR1019950702363A patent/KR100361236B1/en not_active IP Right Cessation
- 1994-10-11 CN CN94190866A patent/CN1080036C/en not_active Expired - Lifetime
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- 1994-10-11 EP EP94927775A patent/EP0673566A1/en not_active Withdrawn
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- 1994-10-11 CA CA002150926A patent/CA2150926C/en not_active Expired - Lifetime
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1995
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FI952858A (en) | 1995-06-09 |
MY112253A (en) | 2001-05-31 |
WO1995010890A1 (en) | 1995-04-20 |
US5808569A (en) | 1998-09-15 |
JP3898218B2 (en) | 2007-03-28 |
CA2150926C (en) | 2003-04-15 |
KR950704864A (en) | 1995-11-20 |
CA2150926A1 (en) | 1995-04-20 |
RU2144261C1 (en) | 2000-01-10 |
EP0673566A1 (en) | 1995-09-27 |
CN1080036C (en) | 2002-02-27 |
CN1116022A (en) | 1996-01-31 |
CN1326269A (en) | 2001-12-12 |
SG55182A1 (en) | 1999-04-27 |
BE1007617A3 (en) | 1995-08-22 |
JPH08505030A (en) | 1996-05-28 |
KR100361236B1 (en) | 2003-03-06 |
FI119459B (en) | 2008-11-14 |
FI952858A0 (en) | 1995-06-09 |
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